A millon years

In the game who wants to live a millon year it took many trys to make it all the way to a millon years

You have to choose a breed that u predict to live a millon years but there is alwas a catch there is drought or cold weather and u have to have the right breed to live a millon year if they cross breed it can create the perfect animal

Over time the animals increase and mutate but it needs to be perfect for the animals to live a millon year.

The animals might be changing but the evoriment changes to and the animal will die or reproduce more

Post 9

I think that breeder have to pick and choose the breeds like the how to live a millon year.there are natural selection but u need artafiacal selection to make a plant worthy to be a cash crop.
The plant can become strong and will be the best breed

Who Wants to Live a Million Years: Analysis of a Natural Selection Simulation

1.  It took me about 5 generations to finally win a game, I think it took me this long because the species I chose had good variations, and passed their traits down to their relatives that allowed them to survive through different climates and were able to survive through the hazards of other species. I think it means that for some species, their survival is limited, due to habitat and traits passed down to them.

2. The phenotypes/phenotype combinations I chose were the ones that could survive through cold, and humid conditions, and prevent other species attacking them. I think they survived the longest because, as Darwin quotes "survival of the fittest" which shows how I won the game using the techniques of choosing the right species of survival.

3. I think that the population of theoretical creatures would be affected by genetic drift because over time, the creatures are going to adapt differently to new environment changes and may have a gene variant change. The evidence of drift I noticed in the game was that over each generation, the organisms/species adapt to other environmental changes and survive through the generations.

4. The alleles/phenotypes that seemed to be dominant are when the species I chose in the game adapted/evolved to the environment, and how the species changed their traits and adaptation skills through the process of different climate and species breeding.

5. When the species face a new environmental change/threat, the way they respond to it dictates their phenotypes of being dominant/recessive, or the way they react and adapt to the change, for example: in cold conditions, if the species react the adaptation properly, will grow fur and hibernate and survive through the winter, in hot conditions, they will shed their skin, when a new large predator joins the scene, the species will usually fight back/run away, for a new tall food source, the surviving species who are tall enough to eat the tomato looking plants in the game will soon breed and exhibit variations and will be able to eat the plant for the next generation.

6. I would improve this simulation biologically by putting in real animal species, that show a realistic example of the animals real life natural selection process. I would also put in description of the environments on how the can effect the species, and lastly I would put on a description of the natural selection process from Charles Darwin himself, and facts about alleles/phenotypes to make it less confusing.

Blog Post 9 Eliot Marinshaw

Question 1: Which part (anatomy) or characteristic of the Brassica oleracea plants seems to exhibit the most variation (greatest number of different forms)? Which part or characteristic of the Brassica oleracea plants seems to show the greatest range of variation (biggest difference between one extreme and its opposite)? Use and include data collected from multiple measurements to support your answer.

1. The part of the plant that had the greatest number of forms had to be the width of the leaf (5 in), and the length of the leaf (13 in) because of the different shape and size compared to the other plants. The other characteristic of the plant had to be the length of the leaf (13 in) compared to the height of the stem (7 in) because of the great difference in size.